Trisomy 21 is associated with variable defects in cytotrophoblast differentiation along the invasive pathway

Aneuploid cells in the placenta are associated with poor pregnancy outcomes, but the mechanisms are unclear. Here, we examined the cytotrophoblast (CTB) differentiation pathway that leads to uterine invasion in pregnancies complicated by trisomy 21 (T21) as compared with their normal counterparts. Surprisingly, we observed a wide spectrum of T21 effects. Morphologically, some samples appeared near normal, while others had extensive fibrinoid deposition and apoptosis of CTBs at the maternal-fetal interface (confirmed by TUNEL labeling). At a molecular level, the cells' expression of stage-specific molecules was variably misregulated. At one end of the spectrum, samples with less apoptosis had relatively normal staining patterns. At the other end, samples with extensive apoptosis showed significantly decreased staining for these antigens. Additional studies confirmed that the effects we observed had functional consequences, because the cells exhibited marked phenotypic alterations in vitro, including a large increase in MMP-9 production, which distinguishes the effects of T21 on CTBs from those of preeclampsia. The morphologic, phenotypic, and functional differences among CTBs from pregnancies complicated by T21 illustrate the importance of the interplay between fetal/placental genotype and maternal influences on pregnancy outcome. Furthermore, our data may explain why a significant number of these pregnancies end in spontaneous abortion while others survive to term.     

Microscopy with ultraviolet surface excitation (MUSE): A novel approach to real‐time inexpensive slide‐free dermatopathology

Traditional histology relies on processing and physically sectioning either frozen or formalin‐fixed paraffin‐embedded (FFPE) tissue into thin slices (typically 4‐6 μm) prior to staining and viewing on a standard wide‐field microscope. Microscopy using ultraviolet (UV) surface excitation (MUSE) represents a novel alternative microscopy method that works with UV excitation using oblique cis‐illumination, which can generate high‐quality images from the cut surface of fresh or fixed tissue after brief staining, with no requirement for fixation, embedding and histological sectioning of tissue specimens. We examined its potential utility in dermatopathology. Concordance between MUSE images and hematoxylin and eosin (H&E) slides was assessed by the scoring of MUSE images on their suitability for identifying 10 selected epidermal and dermal structures obtained from minimally fixed tissue, including stratum corneum, stratum granulosum, stratum spinosum, stratum basale, nerve, vasculature, collagen and elastin, sweat glands, adipose tissue and inflammatory cells, as well as 4 cases of basal cell carcinoma and 1 case of pseudoxanthoma elasticum deparaffinized out of histology blocks. Our results indicate that MUSE can identify nearly all normal skin structures seen on routine H&E as well as some histopathologic features, and appears promising as a fast, reliable and cost‐effective diagnostic approach in dermatopathology.